[1] Danly B G, Blank M, Calame J P, et al. Development and testing of a high-average power, 94-GHz gyroklystron[J]. IEEE Transactions on Plasma Science, 28, 713-726(2000).
[2] Luo Yong. High frequency system beamwave interaction study of gyroklystron amplifiers[D]. Chengdu: University of Electronic Science Technology of China, 2003
[4] Chu K R. The electron cyclotron maser[J]. Reviews of Modern Physics, 76, 489-540(2004).
[5] Levush B, Blank M, Calame J, et al. Modeling and design of millimeter wave gyroklystrons[J]. Physics of Plasmas, 6, 2233-2240(1999).
[6] Latham P E, Lawson W, Irwin V. The design of a 100 mw, Ku band second harmonic gyroklystron experiment[J]. IEEE Transactions on Plasma Science, 22, 804-817(1994).
[7] Vlasov A N, Antonsen T M, Jr Chernin D P, et al. Simulation of microwave devices with external cavities using MAGY[J]. IEEE Transactions on Plasma Science, 30, 1277-1291(2002).
[9] Fliflet A W, Read M E, Chu K R, et al. A self-consistent field theory for gyrotron oscillators: application to a low
[12] Geng Zhihui, Liu Pukun. Design of a Ka-band second harmonic gyroklystron amplifier by using a self-consistent nonlinear simulation[J]. IEEE Transactions on Plasma Science, 34, 534-540(2006).
[13] Zhou Jun, Liu Dagang, Liao Chen, et al. CHIPIC: an efficient code for electromagnetic PIC modeling and simulation[J]. IEEE Transactions on Plasma Science, 37, 2002-2011(2009).
[14] Geng Zhihui. Selfconsistent nonlinear they simulation of millimeter wave gyroklystron amplifier[D]. Beijing: Institute of Electronic, Chinese Academy of Sciences, 2005
[15] Sun Dimin. Theetical experimental study of Wb third harmonic gyrotrons[D]. Beijing: Tsinghua University, 2014